NL2012195C2 - MULTI-LAYER THERMAL INSULATION MATERIAL. - Google Patents

Abstract

A multilayer thermal insulation material comprises at least two infrared transparent layers and at least one infrared reflective layer provided between the infrared transparent layers. The infrared transparent layer comprises at least one corrugated layer. The corrugated layer comprises a plurality of corrugations extending parallel to each other. The corrugated layer is connected to a base layer, with the corrugations facing the infrared reflective layer.

Description

Multi-layer thermal insulation material

The invention relates to a multi-layer thermal insulation material comprising at least two infrared transparent layers and at least one infrared reflective layer located between the infrared transparent layers.

Such a multi-layer thermal insulation material known from NLi 035815 comprises bubble films which are transparent to infrared radiation and an intermediate layer which reflects infrared radiation. The bubble wrap is provided with a plurality of sealed studs, each of which is provided with a fluid. Because the studs are sealed, the fluid is locked in the studs.

Furthermore, the bubble wrap is easily bendable over portions of the bubble wrap located between the studs. With a relatively thin reflective layer, which is also flexible, the multi-layer thermal insulation material is therefore relatively flexible. This has the advantage that it can easily be bent into the desired shape. A drawback of such a flexible insulation material, however, is that additional support is needed to keep it in the desired shape.

The invention has for its object to provide a multi-layer thermal insulation material which is relatively rigid at least in one direction.

This object is achieved with the multilayer thermal insulation material according to the invention in that the infrared transparent layer comprises at least one wave layer, which wave layer comprises a number of waves extending parallel to each other, the waves of the wave layer of a first of the two infrared transparent layers extend at an angle between 0 and 90 degrees with the waves of the wave layer of a second of the two infrared transparent layers.

The waves in the wave layer prevent bending about an axis extending transversely to the waves.

If the waves of all wave layers extend in the same direction, the multi-layer thermal insulation material is flexible about an axis parallel to the waves. The angle here is o degrees.

If the waves of the first wave layer extend transversely to the waves of the second wave layer, an insulation material is obtained which is relatively stiff both parallel to and transversely to the waves of the first wave layer. The angle is 90 degrees.

Other angles are also conceivable, whereby depending on the application, due to the mutual orientation of the waves, the insulating material can be made stiffer in one direction than in another direction.

The infrared reflective layer located between the infrared transparent layers can be of relatively thin design, wherein the infrared reflective layer substantially does not contribute to the stiffness against bending but in which the cost, the weight and the total thickness of the multi-layer thermal insulation material remains limited.

An embodiment of a multi-layer thermal insulation material according to the invention is characterized in that the wave layer is connected to a base layer, wherein the waves are directed towards the infrared reflective layer.

The base layer abuts the tops of the waves and is preferably connected to all waves of the wave layer, whereby the wave layer is strengthened.

The infra-red reflecting layer hereby abuts the tops of the waves remote from the base layer, so that the contact surface between the infra-red reflecting layer and the infra-red transparent layer is relatively small, so that virtually no heat-conducting contact occurs. The contact surface is considerably smaller than when using the bubble film known per se. Between the waves and the infrared reflective layer and between the waves and the base layer there is air that has a good thermal insulating effect.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that each wave extends in a longitudinal direction, the waves being open near the ends.

Because of the open waves, air that is present between the waves and the infrared reflective layer and the base layer can easily flow out and into the waves. This further improves the thermal performance of the insulation material.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that infrared transparent and reflective layers are connected to each other with the aid of H-shaped plastic connecting elements. H-shaped plastic connecting elements comprise a first leg, a second leg extending substantially parallel to the first leg and a bridge part extending substantially transversely between, for example, the center of the first and second leg. After applying the H-shaped plastic connecting element, the first leg rests against an outside of an infrared transparent layer, the second leg rests against an outside of another infrared transparent layer and the bridge part extends through the infrared transparent and reflective lay out. A passage with a relatively small diameter is hereby formed in the layers. The first and second legs and the bridge part are, for example, rod-shaped, whereby the layers are connected to each other over a relatively small surface. The layers are further preferably loosely abutting.

Such H-shaped plastic connecting elements are known, for example, from DE10116574B4. Such H-shaped plastic connecting elements are also known from the clothing industry for attaching price labels to a garment, wherein only a small passage in the garment needs to be made for attaching the H-shaped plastic connecting element.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that the insulation material is provided with a number of sets of two infrared transparent layers and an infrared reflecting layer located between the infrared transparent layers, wherein the waves of the wave layers of the infrared transparent layers facing the infrared reflective layer.

By applying a number of sets, the insulating effect of the insulating material is further increased.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that outer layers of the insulation material are infrared transparent layers, wherein the waves of the wave layers of the infrared transparent layers are directed towards the at least one infrared reflective layer.

This protects the infrared reflective layer well against external influences.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that the infrared reflective layer is provided with a metal layer, the metal comprising at least one element from a group comprising copper, aluminum, cobalt, nickel, silver or gold, or a alloy comprising at least one of these elements.

Such materials have a good reflection of infrared radiation, whereby at least 50% of the infrared radiation is reflected. With various materials, such as for example aluminum, more than 80 to 97% of the infrared radiation can be reflected.

A further embodiment of a multilayer thermal insulation material according to the invention is characterized in that the infrared transparent layer is made of a polymeric plastic which comprises at least one polymeric material from a group comprising polystyrene, polyethylene (PE), polyethylene terephthalate (PET), other polyester ethers, fluoropolymers such as poly-tetra-fluoro-ethylene (PTFE, Teflon ™), ethylene-tetrafluoroethylene copolymer (ETFE), polyvinyl chloride (PVC), nylon, polypropylene (PP) or other polyamides.

Such materials have a good transmission of infrared radiation, whereby at least 50% of the infrared radiation is transmitted. With various materials, more than 80 to 95% of the infrared radiation can be transmitted.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that the base layer and / or the wave layer of the infrared transparent layer has a thickness of 0.01 to 0.2 millimeter.

With such a thickness, a good balance can be obtained between the material costs and the rigidity of the infrared transparent layer.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that the waves of the wave layer of the infrared transparent layer have a height of at least 3 millimeters in a direction extending transversely to the base layer.

Due to a good height, sufficient space is obtained between the base layer and tops of the corrugated layer, in which air is present which also provides the insulating properties.

A further embodiment of a multi-layer thermal insulation material according to the invention is characterized in that the waves of the wave layer of the infrared transparent layer are at a mutual distance of at least 4 millimeters from each other.

Such waves are sufficiently small to prevent unwanted collapse of the waves and sufficiently large to allow sufficient space for air between the base layer and the wave layer.

The invention will be further elucidated with reference to the drawings in which, figure 1 shows a perspective view of a first embodiment of a multi-layer thermal insulation material according to the invention, figure 2 shows a perspective cross-section of a second embodiment of a multi-layer thermal insulation material according to the invention shows.

In the figures, corresponding parts are provided with the same reference numeral.

Figure 1 shows a first embodiment of a multi-layer thermal insulation material 1 according to the invention, which is provided with eight infrared transparent layers 2 and three infrared reflective layers 3.

The infrared transparent layer 2 comprises a flat base layer 4 and wave layer 5. The wave layer 5 comprises a number of waves 6 extending parallel to each other. Between the waves 6 the wave layer 5 is over lines 7 extending parallel to each other, for example by ultrasonic welding with the base layer 4 connected. Between each wave 6 and the base layer 4 there is a semi-cylindrical space 8 in which there is air. The waves 6 extend in a longitudinal direction L, the waves 6 being open near the ends, so that air can freely flow into and out of the semi-cylindrical spaces 8. The waves 6 have a width B of 8 millimeters in a direction extending transversely to the longitudinal direction L and in a direction extending parallel to the base layer 4. The waves 6 have a height H of 4 millimeters in a direction extending transversely to the base layer 4. The base layer 4 and the wave layer 5 have a thickness of 0.01 to 0.2 millimeters.

The infrared transparent layer 2 is made of polyethylene (PE).

Such a transparent layer 2 is known as packaging material from DE102012216768A1. At DE102012216768A1 the waves serve to absorb collision forces.

The infrared reflective layer 3 is a flat aluminum layer in which aluminum is deposited on a plastic carrier layer. The flat aluminum layer has a thickness of, for example, 7 microns. Such an infrared reflective layer 3 reflects at least 85% of infrared radiation.

The multilayer thermal insulation material 1 shown in Figure 1 comprises three superimposed sets 9 of two infrared transparent layers 2 and an infrared reflective layer 3 located between the infrared transparent layers 2, the waves 6 of the wave layers 5 of the infrared transparent layers 2 facing the infrared reflective layer 3. Because the waves 6 are directed to and lie against the infrared reflective layer 3, the contact surface between the infrared transparent layer 2 and the infrared reflective layer 3 is small. Spaces 10 are located between the waves 6 and the infrared reflective layer 3, which extend in the longitudinal direction L and are open at the ends, so that air can freely flow in and out of the spaces 10.

The multi-layer thermal insulation material 1 further comprises two further infrared transparent layers 2, which form the outer layers of the multi-layer thermal insulation material 1. The waves 6 of the wave layers 5 of the outer infrared transparent layers 2 are directed towards the infrared reflective layers 3 located between the outer layers 2.

The infrared transparent layers 2 and the infrared reflective layers 3 lie loosely on top of each other and are connected to each other at a limited number of locations with the aid of H-shaped plastic connecting elements 11. The H-shaped plastic connecting elements 11 will be further explained with reference to Figure 2.

The multilayer thermal insulation material 1 reflects 85 to 95% of the infrared radiation falling on it, whereby good heat insulation is obtained. The insulation material 1 has an insulation value R of, for example, 3.5 to 5 m2K / W.

Due to the waves 6, the insulating material 1 at a bending moment M1 exerted on the insulating material 1 is relatively rigid and rigid about an axis extending parallel to the base plate 4 and transversely to the longitudinal direction L.

Figure 2 shows a second embodiment of a multi-layer thermal insulation material 21 according to the invention, which is provided with eight infrared transparent layers 2 and three infrared reflective layers 3. The layers 2, 3 correspond to the layers 2, 3 shown in Figure 1.

The multi-layer thermal insulation material 21 shown in Figure 2 comprises three superimposed sets 22 of two infrared transparent layers 2 and an infrared reflective layer 3 located between the infrared transparent layers 2. The set 22 differs from the set 9 in that in the set 22 the waves 6 of the wave layers 5 of the two infrared transparent layers 2 extend transversely to each other. The waves 6 of the upper infrared transparent layer 2 of the set 22 shown in figure 2 extend parallel in the longitudinal direction L, while the waves 6 of the lower infrared transparent layer 2 of the set 22 shown in figure 2 extend transversely of the longitudinal direction L .

Owing to the waves 6 extending transversely to each other, the insulating material 1 is at a bending moment Mi exerted on the insulating material 1 about an axis extending parallel to the base plate 4 and transversely to the longitudinal direction L and at a bending moment M2 exerted on the insulating material 1 shaft extending parallel to the longitudinal direction L is relatively rigid and rigid.

Because the insulation material 1 is relatively rigid, it can easily be attached to a wall or to a ceiling of a building, while maintaining a flat shape.

The infrared transparent layers 2 and the infrared reflective layers 3 lie loosely on top of each other and are connected to each other at a limited number of locations with the aid of H-shaped plastic connecting elements. The H-shaped plastic connecting elements n each comprise a first leg 23, a second leg 24 extending substantially parallel to the first leg and a bridge part 25 extending substantially transversely between, for example, the center of the first and second leg 23, 24. leg 23, for example, has a width b1 of 5 to 15 millimeters and a thickness and height of 1 to a few millimeters. The bridge part 25 is wire-shaped and has a diameter of less than 2 millimeters and a length that at least corresponds to the distance between outer layers 2 with loosely superimposed layers 2, 3. The second leg 24 is wire-shaped and has a diameter of less than 2 mm. 2 millimeters and a length b2 of 5 to 20 millimeters.

The second leg 24 and the bridge part 25 of the H-shaped plastic connecting element 11 are shot through the layers 2, 3 from the upper outer layer 2 with the aid of a tool known from, inter alia, the clothing industry, the second leg 24 extends substantially parallel to the bridge part 25 against elastic spring force. When the second leg part 24 and the bridge part 25 are fired through the layers 2, 3, a small passage with a diameter of less than 2 millimeters is formed in the layers 2, 3. As soon as the second leg 24 is located beyond the lower outer layer 2, the second leg 24 extends transversely of the bridge part 25 under elastic spring force.

This makes it possible to loosely connect the layers 2, 3 with a limited number of H-shaped connecting element 11, whereby virtually no heat conduction will occur from the top side to the bottom side or vice versa through the connection elements 11.

It is also possible that the infrared transparent layer 2 made of other materials or combinations of materials such as polystyrene, polyethylene (PE), polyethylene terephthalate (PET) and other polyester ethers, fluoropolymers such as poly-tetra-fluoro-ethylene (PTFE, Teflon ™), or ethylene tetrafluoroethylene copolymer (ETFE), polyvinyl chloride (PVC), nylon, polypropylene (PP), and other polyamides are made.

It is also possible that the infrared reflective layer 3 is made of other materials or combinations of materials such as copper, aluminum, cobalt, nickel, silver, gold, or an alloy comprising at least one of these elements.

It is also possible that the waves 6 of a first infrared transparent layer 2 extend at a different angle between 0 and 90 degrees, for example 30 degrees or 45 degrees with the waves 6 of a second infrared transparent layer 2.

The number of sets 9, 22 can also be larger or smaller than three.

It is also possible to close the ends of the waves and the openings located near the ends between the waves and the other layers on one side or on both sides.

It is also possible to design the infrared transparent layer 2 as a single wave layer 5 without a base layer 4 connected thereto.

It is also possible to design the infrared transparent layer 2 as a base layer 4 with wave layers 5 connected thereto on both sides, wherein the waves of the two wave layers can extend parallel to each other, transversely to each other or at a different angle to each other. Reference number 1 multi-layer thermal insulation material 2 infrared transparent layer 3 infrared reflective layer 4 base layer 5 wave layer 6 wave 7 line 8 semi-cylindrical space 9 set of space n H-shaped plastic connecting element 21 multi-layer thermal insulation material 22 set 23 leg 24 leg 25 bridge section L length direction B width H height

Mi bending moment M2 bending moment bi width b2 length

Claims (12)

A multi-layer thermal insulation material (1, 21) comprising at least two infrared transparent layers and at least one infrared reflective layer (3) located between the infrared transparent layers, characterized in that the infrared transparent layer (2) comprises at least one wave layer (5), which wave layer (5) comprises a number of waves (6) extending parallel to each other, the waves (6) of the wave layer of a first of the two infrared transparent layers being at an angle between 0 and 90 degrees extend with the waves (6) of the wave layer of a second of the two infrared transparent layers. Multi-layer thermal insulation material (1, 21) according to claim 1, characterized in that the wave layer (5) is connected to a base layer (4), the waves (6) facing the infrared reflective layer (3) . Multi-layer thermal insulation material according to one of the preceding claims, characterized in that each wave (6) extends in a longitudinal direction (L), the wave (6) being open near the ends. Multi-layer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that infrared transparent and reflective layers are connected to each other with the aid of H-shaped plastic connecting elements (11). Multilayer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that the insulation material is provided with a number of sets (9, 22) of two infrared transparent layers and an infrared reflective layer located between the infrared transparent layers (3), wherein the waves (6) of the wave layers (5) of the infrared transparent layers are directed towards the infrared reflective layer (3). Multi-layer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that outer layers of the insulation material are infrared transparent layers, wherein the waves (6) from the wave layers of the infrared transparent layers to the at least one infrared reflective layer (3). Multi-layer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that the infrared reflective layer (3) is provided with a metal layer, the metal comprising at least one element from a group comprising copper, aluminum, cobalt, nickel, silver or gold, or an alloy comprising at least one of these elements. Multilayer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that the infrared transparent layer (2) is made of a polymeric plastic comprising at least one polymeric material from a group comprising polystyrene, polyethylene (PE) ), polyethylene terephthalate (PET), other polyester, fluoropolymers such as poly-tetra-fluoroethylene (PTFE, Teflon ™), ethylene-tetrafluoroethylene copolymer (ETFE), polyvinyl chloride (PVC), nylon, polypropylene (PP) or other polyamides. Multilayer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that the base layer (4) of the infrared transparent layer (2) has a thickness of 0.01 to 0.2 millimeters. A multi-layer thermal insulation material (1, 21) according to any one of the preceding claims, characterized in that the wave layer (5) of the infrared transparent layer (2) has a thickness of 0.01 to 0.2 millimeter. A multi-layer thermal insulation material (1, 21) according to any one of the preceding claims, characterized in that the waves (6) of the wave layer (5) of the infrared transparent layer (2) in a transverse direction to the base layer (4) have a height (H) of at least 3 millimeters in the extending direction. Multilayer thermal insulation material (1, 21) according to one of the preceding claims, characterized in that the waves (6) of the wave layer (5) of the infrared transparent layer (2) are at a mutual distance of at least 4 millimeters from each other are located.